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FINAL REPORT - Copy

D
Divay Chadha

The document describes the design and analysis of a car jack using CAD software CATIA and FEA software ANSYS. It was a summer training project completed by two students to fulfill their degree requirements. The project involved modeling a scissor jack in CATIA, analyzing it using ANSYS to determine stresses and efficiency, and optimizing the design to improve the jack's life and performance. The document provides background on different types of jacks, prior research, and specifications and working of scissor jacks to support the project objectives.

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1 DESIGNING & ANALYSIS OF A CAR JACK USING CATIA & ANSYS A SUMMER TRAINING PROJECT REPORT Submitted by DIVAY CHADHA-21213303612 SACHIN KUMAR-19313303612 In partial fulfillment for the award of the degree of BACHELOR OF ENGINEERING in MECHANICAL & AUTOMATION ENGINEERING HMR INSTITUTE OF TECHNOLOGY & MANAGEMENT, HAMIDPUR IP UNIVERSITY: DWARKA 110078 NOVEMBER 2014
2 BONAFIDE CERTIFICATE Certified that this project report “DESIGNING & ANALYSIS OF A CAR JACK USING CATIA & ANSYS” is the bonafide work of “DIVAY CHADHA (21213303612); SACHIN KUMAR (19313303612)” who carried out the project work under my supervision. SIGNATURE SIGNATURE Prof. S.K. GUPTA EHSAAN ASGAR HEAD OF THE DEPARTMENT ASSITANT PROFESSOR Mechanical Engineering Mechanical Engineering HMRITM HMRITM Submitted for viva-voice examination of IP UNIVERSITY, DWARKA held at HMR INSTITUTE OF TECHNOLOGY & MANAGEMENT, HAMIDPUR on __14 NOVEMBER 2014__ INTERNAL EXAMINER EXTERNAL EXAMINER
3 ACKNOWLEDGEMENT We are submitting our gratitude to our Director Dr.S.S. INAMDAR for his care and concern for our welfare throughout our learning carrier. We whole heartedly thank our beloved Chairman SH. ANIL KUMAR GUPTA, for his constant encouragement shown to us during our course of study. We express our sincere thanks to our Head of Mechanical & Automation Engineering Department Prof. S.K. GUPTA, for his most valuable guidance, advice and encouragement in all stages of our project work. We express our deepest gratitude to our project guide EHSAN ASGAR, Assistant Professor, Dept. of Mechanical Engineering and S.N. SHARMA, Trainer (HCL) For their continuous guidance and suggestions. We thank one and all who directly and indirectly helped us to bring this project successful one. We extend our thanks to our mechanical department staff members and to our family whose timely help enabled us to complete our project in time.
4 ABSTRACT A Screw jack is a portable device consisting of a screw mechanism used to raise or lower the load. There are two types of jacks-mechanical and hydraulic Mechanical jacks can be either hand operated or power driven. The hydraulic jack consist of cylinder and piston mechanism Although a jack is a simple device used to raise various types of loads Proper size, strength and stability are essential requirements for the design of the screw jack from safety consideration.
5 CONTENTS 1 INTRODUCTION TO JACKS 2 LITERATURE SURVEY 2.1 EARLIEST JACK DEVELOPMENT 2.1.1 HIS WORK 2.1.2 FURTHER IMPROVEMENTS 3 PROBLEM DEFINITION 4 OBJECTIVE 5 SCISSOR JACK 6 MARKET RESEARCH 7 3-D MODELS (CATIA V5R20) 8 ANALYSIS (ANSYS) 9 CONCLUSION 10 REFERENCES
6 CHAPTER 1 INTRODUCTION 1.1 GENERAL INTRODUCTION Our survey in the regard in several users of vehicles, revealed the facts that mostly some difficult methods were adopted in lifting the vehicles for reconditioning. Now the project is mainly concentrated on this difficulty, such that the vehicle can be lifted from the floor land without application of any impact force. The motorized screw jack has been developed to cater to the needs of small and medium automobile garages, which are normally man powered with minimum skilled labor. In most of the garages the vehicles are lifted by using screw jack. This needs high man power and skilled labour. In order to avoid all such disadvantages, the built-in jack should be designed in such a way that it can be used to lift the vehicle very smoothly without any impact force. The operation is made simple so that even unskilled labour can use it with ease. As automobile market is growing, advance concepts are being implemented to make automobiles more and more versatile and comfortable. Many concepts are implemented day to day to make automobile better and better these days. One such concept is of variable height adjustment in vehicle by adjusting its ground clearance. In this way the vehicle becomes more versatile and can be operated over variety of bad as well as good road conditions. 1.2 CURRENT SCENARIO: WHAT IS A JACK? A mechanical jack is a device which lifts heavy equipment and vehicles so that maintenance can be carried out underneath. Car jacks usually use mechanical advantage to allow a human to lift a vehicle by manual force alone. More powerful jacks use hydraulic power to provide more lift over greater distances. Mechanical jacks are usually rated for maximum lifting capacity.  Automotive jacks are classified as:
7 1. Hydraulic jacks: A. Bottle shape : B. Floor jack :
8 2. Screw Type A. Scissor jack : B. Bumper jack :
9 1.3 CURRENT MECHANISM OF JACK OPERATION Hydraulic jacks:  Hydraulic jacks are typically used for shop work, rather than as an emergency jack to be carried with the vehicle.  In these jacks, by operating the handle, which is a lever (a simple machine), fluid is compressed and routed to an actuating cylinder. This results in lift.  Hydraulic jacks are often used to lift elevators in low and medium rise buildings. WORKING: A hydraulic jack uses a fluid, which is incompressible, that is forced into a cylinder by a pump plunger. Oil is used since it is self-lubricating and stable. When the plunger pulls back, it draws oil out of the reservoir through a suction check valve into the pump chamber. When the plunger moves forward, it pushes the oil through a discharge check valve into the cylinder. The suction valve ball is within the chamber and opens with each draw of the plunger. The discharge valve ball is outside the chamber and opens when the oil is pushed into the cylinder. At this point the suction ball within the chamber is forced shut and oil pressure builds in the cylinder. TYPES OF HYDRAULIC JACKS 1. Floor Jacks: These jacks are primarily used to lift heavy equipment from the surface of the floor. It is more often used to change the tyres of vehicles. 2. Hydraulic Bottle Jacks: Hydraulic bottle are versatile since they can be placed in tight spots and provides good leverage. They have a longer handle as compared to rest of the hydraulic jacks and push up against a lever that gives a lift to the main lift arm. With their use, it is possible to give a greater lift per stroke.
10 3. Long Ram Jacks: In simple terms, it is a hydraulic jack with a long size ram. Its lever handle is quite easy to use. It is primarily used for performing various types of repairing work. 4. Shop Press jacks: They are of great use in press jobs where there arises a need to generate tremendous pressure with minimum effort. SCREW JACKS: A jackscrew is a type of jack which is operated by turning a leadscrew. In the form of a screw jack it is commonly used to lift heavy weights such as the foundations of houses, or large vehicles.  In the case of a screw jack, a small force applied in the horizontal plane is used to raise or lower large load.  A jackscrew's compressive force is obtained through the tension force applied by its lead screw.  Harsh environment applications such as steel mills, mining, oil & gas, and primary metal smelting operations, here screw Jacks are preferred over hydraulics. In these environments where hydraulic cylinders would simply not survive the fluctuating temperatures.  A jackscrew's threads must support heavy loads. In the most heavy-duty applications, such as screw jacks, a square thread or buttress thread is used, because it has the lowest friction. In other application such as actuators, an Acme thread is used, although it has higher friction.
11 TYPES OF SCREW JACKS 1. Scissor jack: A scissor jack is a device constructed with a cross-hatch mechanism, much like a scissor, to lift up a vehicle for repair or storage. It typically works in just a vertical manner. The jack opens and folds closed, applying pressure to the bottom supports along the crossed pattern to move the lift. When closed, they have a diamond shape. Scissor jacks are simple mechanisms used to drive large loads short distances. The power screw design of a common scissor jack reduces the amount of force required by the user to drive the mechanism. Most scissor jacks are similar in design, consisting of four main members driven by a power screw. A scissor jack is operated simply by turning a small crank that is inserted into one end of the scissor jack. This crank is usually "Z" shaped. The end fits into a ring hole mounted on the end of the screw, which is the object of force on the scissor jack. When this crank is turned, the screw turns, and this raises the jack. The screw acts like a gear mechanism. It has teeth (the screw thread), which turn and move the two arms, producing work. Just by turning this screw thread, the scissor jack can lift a vehicle that is several thousand pounds. 2. Bumper jacks: They were used earlier and are not prevalent nowadays.
12 1.4 PROS AND CONS OF BOTH MECHANISMS Screw Jacks and Hydraulic Cylinders each offer their own unique advantages as lifting and positioning devices SCREW JACKS:  Over time, hydraulic cylinders can lose position or “creep” due to loss of pressure at the pump or through the cylinder seal. In some cases, a damaged hydraulic line or hose can cause complete loss of position. This will not happen with Screw Jacks since the primary lifting mechanism (acme thread) is inherently self-locking i.e. the jack will not “creep” even when the drive motor is shut down.  Screw jacks are often preferred for their self-locking characteristics, ability to withstand harsh environments, minimal drive components, and high duty cycles.  Scissor jacks are handy because they are compact when they are in their contracted position.  Harsh environment applications such as steel mills, paper mills, mining, oil & gas, and primary metal smelting operations are the areas where Screw Jacks are preferred over hydraulics. Jacks commonly operate for many years in these environments where hydraulic cylinders would simply not survive the fluctuating temperatures and gritty conditions without frequent breakdown.  Additional benefits of screw jacks include minimal drive components and setup simplicity. Where hydraulics require a pumping device, oil reservoir, and oil lines, Joyce Screw Jacks can be directly connected to a drive motor and a simple on/off control device. HYDRAULIC JACK:  These jacks are sturdier than the scissor jacks and can lift heavier loads.
13 CHAPTER 2 LITERATURE SURVEY 2.1 PAST WORK DONE EARLIEST JACK DEVELOPMENT:  There is evidence of the use of screws in the Ancient Roman world but it was Leonardo da Vinci, in the late 1400s, who first demonstrated the use of a screw jack for lifting loads. HIS DESIGN:  Leonardo design used a threaded worm gear, supported on bearings, that is rotated by the turning of a worm shaft to drive a lifting screw to move the load - instantly recognizable as the principle we use today. FURTHER IMPROVEMENTS: Screw type mechanical jacks were very common for jeeps and trucks of World War II vintage. For example, the World War II jeeps were issued the "Jack, Automobile, Screw type, Capacity 1 and 1/2 ton". With the industrial revolution of the late 18th and 19th centuries came the first use of screws in machine tools, via English inventors such as John Wilkinson and Henry Maudsley. During the early 1880s in Coaticook, a small town near Quebec, a 24-year- old inventor named Frank Henry Sleeper designed a lifting jack. Like da Vinci’s jack, it was a technological innovation because it was based on the principle of the ball bearing for supporting a load and transferred rotary motion, through gearing and a screw, into linear motion for moving the load. The device was efficient, reliable and easy to operate. It was used in the construction of bridges, but mostly by the railroad industry, where it was able to lift locomotives and railway cars. The idea was based on the familiar lever and fulcrum principle and he needed someone to manufacture it
14  There was clearly potential for using this technology for other applications and only 10 years later, in 1940, the first worm gear screw jack, that is instantly recognizable today, was offered by Duff-Norton, for adjusting the heights of truck loading platforms and mill tables. Since then the product has evolved to push, pull, lift, lower and position loads of anything from a few kilos to hundreds of tonnes. One of the biggest single screw jacks made to date is a special Power Jacks E-Series unit that is rated for 350 tonnes even in earthquake conditions for the nuclear industry.
15 CHAPTER 3 PROBLEM DEFINITION  The most common problem encountered while using scissor jack is the instability of jack while giving jerks to loosen the wheel nut. Also the common jack having small base is unable to provide proper support on uneven surface esp. off-road and no inclination in that jack is tolerable.
16 CHAPTER 4 OBJECTIVE  The project relates to the designing of simple scissor jack and its analysis along with structural improvements to make such a modified jack that is very stable and can take enough load on uneven surfaces and somewhat inclination is also allowed.  The project also aims at designing and finding stresses, efficiency, expected life of screw. We endeavor to develop a scissor jack such that it is cost effective, having a long life and can be handled roughly.
17 CHAPTER 5 SCISSOR JACK 5.1 Specifications  The term "scissor jack" describes a wide variety of tools that all follow the same principle: using crossed beams to lift something. They do this by acting on the object they are lifting in a diagonal manner; the lift on the right side lifts the object from its left side and vice versa. This allows the user to store the jack when it is not in use (with the diagonal beams flat) and to expand it when it is needed. Fig. 5.1 Fig. 5.2  The major specification of scissor lifts is that they are all symmetrical. In order to work, the distance from the loaded point to the cross point must be the same as the distance from the cross point to the ground. This ensures that weight is distributed equally throughout the scissor lift beams.  Since scissor lifts have such a wide variety of use, they also have a wide variety of power sources. Scissor lifts for lifting cars can be powered electrically, hydraulically and of course mechanically. On the other end of the spectrum, industrial scissor lifts that people stand on are often powered by diesel, although electrical options do exist.
18  Scissor lifts basically fall into two categories: single scissor lifts and multiple scissor lifts. A single scissor lift has just two crossbeams and one "x." This means it can only go so high because the length of the crossbeams restricts the height of the lift, and making them too long would make it unstable. On the other hand, multiple lifts have beams crossing each other, and then attaching to more beams that go the opposite direction. This allows the scissor lift to rise higher. 5.2 Assembly A scissor jack has four main pieces of metal and two base ends. The four metal pieces are all connected at the corners with a bolt that allows the corners to swivel. A screw thread runs across this assembly and through the corners. As the screw thread is turned, the jack arms travel across it and collapse or come together, forming a straight line when closed. Then, moving back the other way, they raise and come together. When opened, the four metal arms contract together, coming together at the middle, raising the jack. When closed, the arms spread back apart and the jack closes or flattens out again. 5.3Working A scissor jack uses a simple theory of gears to get its power. As the screw section is turned, two ends of the jack move closer together. Because the gears of the screw are pushing up the arms, the amount of force being applied is multiplied. It takes a very small amount of force to turn the crank handle, yet that action causes the brace arms to slide across and together. As this happens the arms extend upward. The car's gravitational weight is not enough to prevent the jack from opening or to stop the screw from turning, since it is not applying force directly to it. If you were to put pressure directly on the crank, or lean your weight against the crank, the person would not be able to turn it, even though your weight is a small percentage of cars.
19 5.4 Components  Frame  Power screw  Rivets  Coupling nut  Crank 5.4.1 Frame: The entire frame of the scissor jack consists of links (top and bottom), base frame and support frame. The frame is manufactured by sheet metal processes and forming by low-medium carbon steel. 5.4.2 Power screw: Power screws are used to convert rotary motion in to translational motion. It is also called translational screw. They find use in machines such as universal tensile testing machines, machine tools, automotive jacks, vises; aircraft flap extenders, trench braces, linear actuators, adjustable floor posts, micrometers, and C-clamps. A screw thread is formed by cutting a continuous helical groove around the cylinder. These grooves are cut either left hand or right hand. The majority of screws are tightened by clockwise rotation, which is termed a right-hand thread. Screws with left-hand threads are used in exceptional cases. For example, anticlockwise forces are applied to the screw (which would work to undo a right-hand thread), a left-hand- threaded screw would be an appropriate choice. Power screws are typically made from carbon steel, alloy steel, or stainless steel and they are usually used with bronze, plastic, or steel mating nuts. Bronze and plastic nuts are popular for
20 higher duty applications and they provide low coefficients of friction for minimizing drive torques. There are important terms and figures that need to be understood before designing power screws: 1. Pitch: is the distance from a point on one thread to the corresponding thread on the next adjacent thread, measured parallel to the axial plane. 2. Lead: is the distance the screw would advance relative to the nut in one rotation. For single thread screw, lead is equal to pitch. 3. Helix Angle: is related to the lead and the mean radius by the equation below; Fig. 5.3 5.4.2.1 Basics of power screws Power screws provide a compact means for transmitting motion and power. They are ideal for replacing hydraulic and pneumatic drive systems as they require no compressors, pumps, piping, filters, tanks, valves or any other support items required by these systems. Also, screws don't leak so there are no problems with seals which are so common to hydraulic and pneumatic systems. And, screw systems are quiet running - no noisy compressors, pumps or exhaust valves. Screw systems are simple, reliable and easy to utilize.
21 5.4.2.2 Power screw motions There are four distinct motion converting actions that can be produced by power screws and nuts. The two most common involve torque conversion to thrust. In Figure 1, the screw is rotated (torqued) and the nut moves linearly producing thrust or the nut is rotated (torqued) and the screw moves linearly. The two less common motions involve thrust conversion to torque. In Figure 2, the nut undergoes a linear force (thrust) and the screw rotates or the screw undergoes a linear force (thrust) and the nut rotates. These two motions are commonly referred to as "back driving", "overhauling", or, improperly, "reversing". Fig. 5.4 Fig. 5.5 5.4.2.3 Types of power screws There are 3 types of screw threads used in power screws 1. Square threads:  Is used for power transmission in either direction  Results in maximum efficiency and minimum  It is employed in screw jacks and clamps 2. Acme threads:  It is a modification of square thread  Efficiency is lower than square threads  The slope increases the area for shear
22  It is easily manufactured 3. Buttress Thread:  It is used when large forces act along the screw axis in one direction only.  It has higher efficiency like square threads and ease of cutting like acme threads.  It is the strongest thread of all  It has limited use of power transmission 5.4.3 Rivets: A rivet is a permanent mechanical fastener. Before being installed a rivet consists of a smooth cylindrical shaft with a head on one end. The end opposite the head is called the buck- tail. On installation the rivet is placed in a punched or pre-drilled hole, and the tail is upset, or bucked (i.e. deformed), so that it expands to about 1.5 times the original shaft diameter, holding the rivet in place. To distinguish between the two ends of the rivet, the original head is called the factory head and the deformed end is called the shop head or buck-tail. 5.4.4 Coupling nut: A coupling nut is a threaded fastener for joining two male threads, most commonly threaded rod. The outside of the fastener is usually a hex so a wrench can hold it. Variations include reducing coupling nuts, for joining two different size threads; sight hole coupling nuts, which have a sight hole for observing the amount of engagement; and coupling nuts with left- handed threads. 5.4.5 Crank A crank is an arm keyed at right angles to the end of a shaft, by which motion is imparted to the power screw .It mainly suffers from torsional stresses so medium carbon steel is used as it combines merits of malleability and sufficient torsional strength.
23 CHAPTER 6 MARKET RESEARCH 6.1 Product Comparison Below are analyses two other car jacks that are similar to the jack I wish to design. They represent the two primary models of scissor jacks available; those powered by electricity and those that require manual input. Picture Features Pros Cons Fig 6.1  Can lift up to 990kg  Electric motor powered by a 12V DC power source.  Extends 13”, compacts to less than 5”.  7’ power cord.  Weighs 9kgs.  The electric motor makes operating the jack simple and easy.  Can operate jack away from the car.  The added weight of the electric motor hurts fuel economy.  The motor adds cost and the increased complexity of the system creates more opportunity for failure.  Need of an electrical power source could be a hindrance when battery power is not adequate.
24 Fig. 6.2  Lifts 1133 kg.  Extends from 3.75”- 15.4”.  Mechanical input required.  The jack’s simple design minimizes cost , size and weight, so it can be stored easily.  Does not rely on electricity.  Operating the crank can be difficult.  Required to be near (practically underneath a 2,000kg object to operate.  Like the product above, there is no stability provided from the sides.  Tools to raise the jack are not interchangeable. It can be seen that the overall concept of the scissor jack is constant and that any new product will be based on that concept.
25 CHAPTER 7 3-D MODELS (CATIA V5R20) 7.1 Parts Fig 7.1 Fig 7.2
26 Fig 7.3 Fig 7.4
27 Fig 7.5 Fig 7.6
28 7.2 Assembly Fig 7.7
29 CHAPTER 8 ANALYSIS (ANSYS) Fig 8.1 STRESS ON JACK BASE
30 CHAPTER 9 CONCLUSION Scissor Jacks are the ideal product to push, pull, lift, lower and position loads of anything from a hundred of kilograms to a couple of tonnes. The need has long existed for an improved portable jack for automotive vehicles. It is highly desirable that a jack become available that can be operated alternatively from inside the vehicle or from a location of safety off the road on which the vehicle is located. Such a jack should desirably be light enough and be compact enough so that it can be stored in an automobile trunk, can be lifted up and carried by most adults to its position of use, and yet be capable of lifting a wheel of a 4,000-5,000 pounds vehicle off the ground. Further, it should be stable and easily controllable so that jacking can be done from a position of safety. It should be easily movable either to a position underneath the axle of the vehicle or some other reinforced support surface designed to be engaged by a jack. Thus, the product has been developed considering all the above requirements. This particular design of the scissor jack will prove to be beneficial in lifting and lowering of loads.
31 CHAPTER 10 REFERENCES 10.1 Books referred  Materials and heat treatment by O.P. khanna  Design of machine elements by khurmi  Strength of materials by R.K. rajput  A textbook of machine design by P.C.Sharma and D.K.Agarwal, S.K.Kataria and sons, 2006.  A text book of machine drawing by R.S Khurmi, S. Chand and Co. Ltd., 2005.  Mechanical engineering design by Joseph E. Shigley, McGraw Hill, 1986. 10.2 Websites referred  youtube.com(Davison Design: Jack 'N Stand Animated Video)  google.com  scribd.com  Wikipedia.com  Howstuffworks.com  Sciencedirect.com  B2bhydrualicjacks.com

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FINAL REPORT - Copy

  • 1. 1 DESIGNING & ANALYSIS OF A CAR JACK USING CATIA & ANSYS A SUMMER TRAINING PROJECT REPORT Submitted by DIVAY CHADHA-21213303612 SACHIN KUMAR-19313303612 In partial fulfillment for the award of the degree of BACHELOR OF ENGINEERING in MECHANICAL & AUTOMATION ENGINEERING HMR INSTITUTE OF TECHNOLOGY & MANAGEMENT, HAMIDPUR IP UNIVERSITY: DWARKA 110078 NOVEMBER 2014
  • 2. 2 BONAFIDE CERTIFICATE Certified that this project report “DESIGNING & ANALYSIS OF A CAR JACK USING CATIA & ANSYS” is the bonafide work of “DIVAY CHADHA (21213303612); SACHIN KUMAR (19313303612)” who carried out the project work under my supervision. SIGNATURE SIGNATURE Prof. S.K. GUPTA EHSAAN ASGAR HEAD OF THE DEPARTMENT ASSITANT PROFESSOR Mechanical Engineering Mechanical Engineering HMRITM HMRITM Submitted for viva-voice examination of IP UNIVERSITY, DWARKA held at HMR INSTITUTE OF TECHNOLOGY & MANAGEMENT, HAMIDPUR on __14 NOVEMBER 2014__ INTERNAL EXAMINER EXTERNAL EXAMINER
  • 3. 3 ACKNOWLEDGEMENT We are submitting our gratitude to our Director Dr.S.S. INAMDAR for his care and concern for our welfare throughout our learning carrier. We whole heartedly thank our beloved Chairman SH. ANIL KUMAR GUPTA, for his constant encouragement shown to us during our course of study. We express our sincere thanks to our Head of Mechanical & Automation Engineering Department Prof. S.K. GUPTA, for his most valuable guidance, advice and encouragement in all stages of our project work. We express our deepest gratitude to our project guide EHSAN ASGAR, Assistant Professor, Dept. of Mechanical Engineering and S.N. SHARMA, Trainer (HCL) For their continuous guidance and suggestions. We thank one and all who directly and indirectly helped us to bring this project successful one. We extend our thanks to our mechanical department staff members and to our family whose timely help enabled us to complete our project in time.
  • 4. 4 ABSTRACT A Screw jack is a portable device consisting of a screw mechanism used to raise or lower the load. There are two types of jacks-mechanical and hydraulic Mechanical jacks can be either hand operated or power driven. The hydraulic jack consist of cylinder and piston mechanism Although a jack is a simple device used to raise various types of loads Proper size, strength and stability are essential requirements for the design of the screw jack from safety consideration.
  • 5. 5 CONTENTS 1 INTRODUCTION TO JACKS 2 LITERATURE SURVEY 2.1 EARLIEST JACK DEVELOPMENT 2.1.1 HIS WORK 2.1.2 FURTHER IMPROVEMENTS 3 PROBLEM DEFINITION 4 OBJECTIVE 5 SCISSOR JACK 6 MARKET RESEARCH 7 3-D MODELS (CATIA V5R20) 8 ANALYSIS (ANSYS) 9 CONCLUSION 10 REFERENCES
  • 6. 6 CHAPTER 1 INTRODUCTION 1.1 GENERAL INTRODUCTION Our survey in the regard in several users of vehicles, revealed the facts that mostly some difficult methods were adopted in lifting the vehicles for reconditioning. Now the project is mainly concentrated on this difficulty, such that the vehicle can be lifted from the floor land without application of any impact force. The motorized screw jack has been developed to cater to the needs of small and medium automobile garages, which are normally man powered with minimum skilled labor. In most of the garages the vehicles are lifted by using screw jack. This needs high man power and skilled labour. In order to avoid all such disadvantages, the built-in jack should be designed in such a way that it can be used to lift the vehicle very smoothly without any impact force. The operation is made simple so that even unskilled labour can use it with ease. As automobile market is growing, advance concepts are being implemented to make automobiles more and more versatile and comfortable. Many concepts are implemented day to day to make automobile better and better these days. One such concept is of variable height adjustment in vehicle by adjusting its ground clearance. In this way the vehicle becomes more versatile and can be operated over variety of bad as well as good road conditions. 1.2 CURRENT SCENARIO: WHAT IS A JACK? A mechanical jack is a device which lifts heavy equipment and vehicles so that maintenance can be carried out underneath. Car jacks usually use mechanical advantage to allow a human to lift a vehicle by manual force alone. More powerful jacks use hydraulic power to provide more lift over greater distances. Mechanical jacks are usually rated for maximum lifting capacity.  Automotive jacks are classified as:
  • 7. 7 1. Hydraulic jacks: A. Bottle shape : B. Floor jack :
  • 8. 8 2. Screw Type A. Scissor jack : B. Bumper jack :
  • 9. 9 1.3 CURRENT MECHANISM OF JACK OPERATION Hydraulic jacks:  Hydraulic jacks are typically used for shop work, rather than as an emergency jack to be carried with the vehicle.  In these jacks, by operating the handle, which is a lever (a simple machine), fluid is compressed and routed to an actuating cylinder. This results in lift.  Hydraulic jacks are often used to lift elevators in low and medium rise buildings. WORKING: A hydraulic jack uses a fluid, which is incompressible, that is forced into a cylinder by a pump plunger. Oil is used since it is self-lubricating and stable. When the plunger pulls back, it draws oil out of the reservoir through a suction check valve into the pump chamber. When the plunger moves forward, it pushes the oil through a discharge check valve into the cylinder. The suction valve ball is within the chamber and opens with each draw of the plunger. The discharge valve ball is outside the chamber and opens when the oil is pushed into the cylinder. At this point the suction ball within the chamber is forced shut and oil pressure builds in the cylinder. TYPES OF HYDRAULIC JACKS 1. Floor Jacks: These jacks are primarily used to lift heavy equipment from the surface of the floor. It is more often used to change the tyres of vehicles. 2. Hydraulic Bottle Jacks: Hydraulic bottle are versatile since they can be placed in tight spots and provides good leverage. They have a longer handle as compared to rest of the hydraulic jacks and push up against a lever that gives a lift to the main lift arm. With their use, it is possible to give a greater lift per stroke.
  • 10. 10 3. Long Ram Jacks: In simple terms, it is a hydraulic jack with a long size ram. Its lever handle is quite easy to use. It is primarily used for performing various types of repairing work. 4. Shop Press jacks: They are of great use in press jobs where there arises a need to generate tremendous pressure with minimum effort. SCREW JACKS: A jackscrew is a type of jack which is operated by turning a leadscrew. In the form of a screw jack it is commonly used to lift heavy weights such as the foundations of houses, or large vehicles.  In the case of a screw jack, a small force applied in the horizontal plane is used to raise or lower large load.  A jackscrew's compressive force is obtained through the tension force applied by its lead screw.  Harsh environment applications such as steel mills, mining, oil & gas, and primary metal smelting operations, here screw Jacks are preferred over hydraulics. In these environments where hydraulic cylinders would simply not survive the fluctuating temperatures.  A jackscrew's threads must support heavy loads. In the most heavy-duty applications, such as screw jacks, a square thread or buttress thread is used, because it has the lowest friction. In other application such as actuators, an Acme thread is used, although it has higher friction.
  • 11. 11 TYPES OF SCREW JACKS 1. Scissor jack: A scissor jack is a device constructed with a cross-hatch mechanism, much like a scissor, to lift up a vehicle for repair or storage. It typically works in just a vertical manner. The jack opens and folds closed, applying pressure to the bottom supports along the crossed pattern to move the lift. When closed, they have a diamond shape. Scissor jacks are simple mechanisms used to drive large loads short distances. The power screw design of a common scissor jack reduces the amount of force required by the user to drive the mechanism. Most scissor jacks are similar in design, consisting of four main members driven by a power screw. A scissor jack is operated simply by turning a small crank that is inserted into one end of the scissor jack. This crank is usually "Z" shaped. The end fits into a ring hole mounted on the end of the screw, which is the object of force on the scissor jack. When this crank is turned, the screw turns, and this raises the jack. The screw acts like a gear mechanism. It has teeth (the screw thread), which turn and move the two arms, producing work. Just by turning this screw thread, the scissor jack can lift a vehicle that is several thousand pounds. 2. Bumper jacks: They were used earlier and are not prevalent nowadays.
  • 12. 12 1.4 PROS AND CONS OF BOTH MECHANISMS Screw Jacks and Hydraulic Cylinders each offer their own unique advantages as lifting and positioning devices SCREW JACKS:  Over time, hydraulic cylinders can lose position or “creep” due to loss of pressure at the pump or through the cylinder seal. In some cases, a damaged hydraulic line or hose can cause complete loss of position. This will not happen with Screw Jacks since the primary lifting mechanism (acme thread) is inherently self-locking i.e. the jack will not “creep” even when the drive motor is shut down.  Screw jacks are often preferred for their self-locking characteristics, ability to withstand harsh environments, minimal drive components, and high duty cycles.  Scissor jacks are handy because they are compact when they are in their contracted position.  Harsh environment applications such as steel mills, paper mills, mining, oil & gas, and primary metal smelting operations are the areas where Screw Jacks are preferred over hydraulics. Jacks commonly operate for many years in these environments where hydraulic cylinders would simply not survive the fluctuating temperatures and gritty conditions without frequent breakdown.  Additional benefits of screw jacks include minimal drive components and setup simplicity. Where hydraulics require a pumping device, oil reservoir, and oil lines, Joyce Screw Jacks can be directly connected to a drive motor and a simple on/off control device. HYDRAULIC JACK:  These jacks are sturdier than the scissor jacks and can lift heavier loads.
  • 13. 13 CHAPTER 2 LITERATURE SURVEY 2.1 PAST WORK DONE EARLIEST JACK DEVELOPMENT:  There is evidence of the use of screws in the Ancient Roman world but it was Leonardo da Vinci, in the late 1400s, who first demonstrated the use of a screw jack for lifting loads. HIS DESIGN:  Leonardo design used a threaded worm gear, supported on bearings, that is rotated by the turning of a worm shaft to drive a lifting screw to move the load - instantly recognizable as the principle we use today. FURTHER IMPROVEMENTS: Screw type mechanical jacks were very common for jeeps and trucks of World War II vintage. For example, the World War II jeeps were issued the "Jack, Automobile, Screw type, Capacity 1 and 1/2 ton". With the industrial revolution of the late 18th and 19th centuries came the first use of screws in machine tools, via English inventors such as John Wilkinson and Henry Maudsley. During the early 1880s in Coaticook, a small town near Quebec, a 24-year- old inventor named Frank Henry Sleeper designed a lifting jack. Like da Vinci’s jack, it was a technological innovation because it was based on the principle of the ball bearing for supporting a load and transferred rotary motion, through gearing and a screw, into linear motion for moving the load. The device was efficient, reliable and easy to operate. It was used in the construction of bridges, but mostly by the railroad industry, where it was able to lift locomotives and railway cars. The idea was based on the familiar lever and fulcrum principle and he needed someone to manufacture it
  • 14. 14  There was clearly potential for using this technology for other applications and only 10 years later, in 1940, the first worm gear screw jack, that is instantly recognizable today, was offered by Duff-Norton, for adjusting the heights of truck loading platforms and mill tables. Since then the product has evolved to push, pull, lift, lower and position loads of anything from a few kilos to hundreds of tonnes. One of the biggest single screw jacks made to date is a special Power Jacks E-Series unit that is rated for 350 tonnes even in earthquake conditions for the nuclear industry.
  • 15. 15 CHAPTER 3 PROBLEM DEFINITION  The most common problem encountered while using scissor jack is the instability of jack while giving jerks to loosen the wheel nut. Also the common jack having small base is unable to provide proper support on uneven surface esp. off-road and no inclination in that jack is tolerable.
  • 16. 16 CHAPTER 4 OBJECTIVE  The project relates to the designing of simple scissor jack and its analysis along with structural improvements to make such a modified jack that is very stable and can take enough load on uneven surfaces and somewhat inclination is also allowed.  The project also aims at designing and finding stresses, efficiency, expected life of screw. We endeavor to develop a scissor jack such that it is cost effective, having a long life and can be handled roughly.
  • 17. 17 CHAPTER 5 SCISSOR JACK 5.1 Specifications  The term "scissor jack" describes a wide variety of tools that all follow the same principle: using crossed beams to lift something. They do this by acting on the object they are lifting in a diagonal manner; the lift on the right side lifts the object from its left side and vice versa. This allows the user to store the jack when it is not in use (with the diagonal beams flat) and to expand it when it is needed. Fig. 5.1 Fig. 5.2  The major specification of scissor lifts is that they are all symmetrical. In order to work, the distance from the loaded point to the cross point must be the same as the distance from the cross point to the ground. This ensures that weight is distributed equally throughout the scissor lift beams.  Since scissor lifts have such a wide variety of use, they also have a wide variety of power sources. Scissor lifts for lifting cars can be powered electrically, hydraulically and of course mechanically. On the other end of the spectrum, industrial scissor lifts that people stand on are often powered by diesel, although electrical options do exist.
  • 18. 18  Scissor lifts basically fall into two categories: single scissor lifts and multiple scissor lifts. A single scissor lift has just two crossbeams and one "x." This means it can only go so high because the length of the crossbeams restricts the height of the lift, and making them too long would make it unstable. On the other hand, multiple lifts have beams crossing each other, and then attaching to more beams that go the opposite direction. This allows the scissor lift to rise higher. 5.2 Assembly A scissor jack has four main pieces of metal and two base ends. The four metal pieces are all connected at the corners with a bolt that allows the corners to swivel. A screw thread runs across this assembly and through the corners. As the screw thread is turned, the jack arms travel across it and collapse or come together, forming a straight line when closed. Then, moving back the other way, they raise and come together. When opened, the four metal arms contract together, coming together at the middle, raising the jack. When closed, the arms spread back apart and the jack closes or flattens out again. 5.3Working A scissor jack uses a simple theory of gears to get its power. As the screw section is turned, two ends of the jack move closer together. Because the gears of the screw are pushing up the arms, the amount of force being applied is multiplied. It takes a very small amount of force to turn the crank handle, yet that action causes the brace arms to slide across and together. As this happens the arms extend upward. The car's gravitational weight is not enough to prevent the jack from opening or to stop the screw from turning, since it is not applying force directly to it. If you were to put pressure directly on the crank, or lean your weight against the crank, the person would not be able to turn it, even though your weight is a small percentage of cars.
  • 19. 19 5.4 Components  Frame  Power screw  Rivets  Coupling nut  Crank 5.4.1 Frame: The entire frame of the scissor jack consists of links (top and bottom), base frame and support frame. The frame is manufactured by sheet metal processes and forming by low-medium carbon steel. 5.4.2 Power screw: Power screws are used to convert rotary motion in to translational motion. It is also called translational screw. They find use in machines such as universal tensile testing machines, machine tools, automotive jacks, vises; aircraft flap extenders, trench braces, linear actuators, adjustable floor posts, micrometers, and C-clamps. A screw thread is formed by cutting a continuous helical groove around the cylinder. These grooves are cut either left hand or right hand. The majority of screws are tightened by clockwise rotation, which is termed a right-hand thread. Screws with left-hand threads are used in exceptional cases. For example, anticlockwise forces are applied to the screw (which would work to undo a right-hand thread), a left-hand- threaded screw would be an appropriate choice. Power screws are typically made from carbon steel, alloy steel, or stainless steel and they are usually used with bronze, plastic, or steel mating nuts. Bronze and plastic nuts are popular for
  • 20. 20 higher duty applications and they provide low coefficients of friction for minimizing drive torques. There are important terms and figures that need to be understood before designing power screws: 1. Pitch: is the distance from a point on one thread to the corresponding thread on the next adjacent thread, measured parallel to the axial plane. 2. Lead: is the distance the screw would advance relative to the nut in one rotation. For single thread screw, lead is equal to pitch. 3. Helix Angle: is related to the lead and the mean radius by the equation below; Fig. 5.3 5.4.2.1 Basics of power screws Power screws provide a compact means for transmitting motion and power. They are ideal for replacing hydraulic and pneumatic drive systems as they require no compressors, pumps, piping, filters, tanks, valves or any other support items required by these systems. Also, screws don't leak so there are no problems with seals which are so common to hydraulic and pneumatic systems. And, screw systems are quiet running - no noisy compressors, pumps or exhaust valves. Screw systems are simple, reliable and easy to utilize.
  • 21. 21 5.4.2.2 Power screw motions There are four distinct motion converting actions that can be produced by power screws and nuts. The two most common involve torque conversion to thrust. In Figure 1, the screw is rotated (torqued) and the nut moves linearly producing thrust or the nut is rotated (torqued) and the screw moves linearly. The two less common motions involve thrust conversion to torque. In Figure 2, the nut undergoes a linear force (thrust) and the screw rotates or the screw undergoes a linear force (thrust) and the nut rotates. These two motions are commonly referred to as "back driving", "overhauling", or, improperly, "reversing". Fig. 5.4 Fig. 5.5 5.4.2.3 Types of power screws There are 3 types of screw threads used in power screws 1. Square threads:  Is used for power transmission in either direction  Results in maximum efficiency and minimum  It is employed in screw jacks and clamps 2. Acme threads:  It is a modification of square thread  Efficiency is lower than square threads  The slope increases the area for shear
  • 22. 22  It is easily manufactured 3. Buttress Thread:  It is used when large forces act along the screw axis in one direction only.  It has higher efficiency like square threads and ease of cutting like acme threads.  It is the strongest thread of all  It has limited use of power transmission 5.4.3 Rivets: A rivet is a permanent mechanical fastener. Before being installed a rivet consists of a smooth cylindrical shaft with a head on one end. The end opposite the head is called the buck- tail. On installation the rivet is placed in a punched or pre-drilled hole, and the tail is upset, or bucked (i.e. deformed), so that it expands to about 1.5 times the original shaft diameter, holding the rivet in place. To distinguish between the two ends of the rivet, the original head is called the factory head and the deformed end is called the shop head or buck-tail. 5.4.4 Coupling nut: A coupling nut is a threaded fastener for joining two male threads, most commonly threaded rod. The outside of the fastener is usually a hex so a wrench can hold it. Variations include reducing coupling nuts, for joining two different size threads; sight hole coupling nuts, which have a sight hole for observing the amount of engagement; and coupling nuts with left- handed threads. 5.4.5 Crank A crank is an arm keyed at right angles to the end of a shaft, by which motion is imparted to the power screw .It mainly suffers from torsional stresses so medium carbon steel is used as it combines merits of malleability and sufficient torsional strength.
  • 23. 23 CHAPTER 6 MARKET RESEARCH 6.1 Product Comparison Below are analyses two other car jacks that are similar to the jack I wish to design. They represent the two primary models of scissor jacks available; those powered by electricity and those that require manual input. Picture Features Pros Cons Fig 6.1  Can lift up to 990kg  Electric motor powered by a 12V DC power source.  Extends 13”, compacts to less than 5”.  7’ power cord.  Weighs 9kgs.  The electric motor makes operating the jack simple and easy.  Can operate jack away from the car.  The added weight of the electric motor hurts fuel economy.  The motor adds cost and the increased complexity of the system creates more opportunity for failure.  Need of an electrical power source could be a hindrance when battery power is not adequate.
  • 24. 24 Fig. 6.2  Lifts 1133 kg.  Extends from 3.75”- 15.4”.  Mechanical input required.  The jack’s simple design minimizes cost , size and weight, so it can be stored easily.  Does not rely on electricity.  Operating the crank can be difficult.  Required to be near (practically underneath a 2,000kg object to operate.  Like the product above, there is no stability provided from the sides.  Tools to raise the jack are not interchangeable. It can be seen that the overall concept of the scissor jack is constant and that any new product will be based on that concept.
  • 25. 25 CHAPTER 7 3-D MODELS (CATIA V5R20) 7.1 Parts Fig 7.1 Fig 7.2
  • 29. 29 CHAPTER 8 ANALYSIS (ANSYS) Fig 8.1 STRESS ON JACK BASE
  • 30. 30 CHAPTER 9 CONCLUSION Scissor Jacks are the ideal product to push, pull, lift, lower and position loads of anything from a hundred of kilograms to a couple of tonnes. The need has long existed for an improved portable jack for automotive vehicles. It is highly desirable that a jack become available that can be operated alternatively from inside the vehicle or from a location of safety off the road on which the vehicle is located. Such a jack should desirably be light enough and be compact enough so that it can be stored in an automobile trunk, can be lifted up and carried by most adults to its position of use, and yet be capable of lifting a wheel of a 4,000-5,000 pounds vehicle off the ground. Further, it should be stable and easily controllable so that jacking can be done from a position of safety. It should be easily movable either to a position underneath the axle of the vehicle or some other reinforced support surface designed to be engaged by a jack. Thus, the product has been developed considering all the above requirements. This particular design of the scissor jack will prove to be beneficial in lifting and lowering of loads.
  • 31. 31 CHAPTER 10 REFERENCES 10.1 Books referred  Materials and heat treatment by O.P. khanna  Design of machine elements by khurmi  Strength of materials by R.K. rajput  A textbook of machine design by P.C.Sharma and D.K.Agarwal, S.K.Kataria and sons, 2006.  A text book of machine drawing by R.S Khurmi, S. Chand and Co. Ltd., 2005.  Mechanical engineering design by Joseph E. Shigley, McGraw Hill, 1986. 10.2 Websites referred  youtube.com(Davison Design: Jack 'N Stand Animated Video)  google.com  scribd.com  Wikipedia.com  Howstuffworks.com  Sciencedirect.com  B2bhydrualicjacks.com